Celestial navigation system for an autonomous vehicle

ABSTRACT

A navigation control system for an autonomous vehicle comprises a transmitter and an autonomous vehicle. The transmitter comprises an emitter for emitting at least one signal, a power source for powering the emitter, a device for capturing wireless energy to charge the power source, and a printed circuit board for converting the captured wireless energy to a form for charging the power source. The autonomous vehicle operates within a working area and comprises a receiver for detecting the at least one signal emitted by the emitter, and a processor for determining a relative location of the autonomous vehicle within the working area based on the signal emitted by the emitter.

This application is a continuation-in-part of U.S. patent applicationSer. No. 12/415,554, filed Mar. 3, 2009 and U.S. patent application Ser.No. 12/415,512, filed Mar. 3, 2009. These two Applications arecontinuations of U.S. patent application Ser. No. 11/176,048, filed Jul.7, 2005, which claims priority to and incorporates by reference U.S.Provisional Patent Application No. 60/586,046, entitled “CelestialNavigation System for an Autonomous vehicle,” filed on Jul. 7, 2004.

The present teachings relate to robotic systems and, more specifically,to navigation systems for autonomous vehicles.

BACKGROUND

Autonomous vehicles including robotic devices are becoming moreprevalent today and are used to perform tasks traditionally consideredmundane, time-consuming, or dangerous. As programming technologyincreases, so does the demand for robotic devices that can navigatearound a complex environment or worming space with little or noassistance from a human operator.

Autonomous vehicles and associated controls, navigation systems, andother related systems are being developed. For example, U.S. Pat. No.6,594,844 discloses a Robot Obstacle Detection System, the disclosure ofwhich is hereby incorporated by reference in its entirety. Additionalrobot control and navigation systems, and other related systems, aredisclosed in PCT Published Patent Application No WO 20041025947, and inU.S. Pat. Nos. 6,809,490, 6,690,134, 6,781,338, 7,024,478, 6,883,201,and 7,332,690, the disclosures of which are hereby incorporated byreference in their entireties.

Many autonomous vehicles navigate a Working space by moving randomlyuntil an obstacle is encountered. Generally, these types of vehicleshave on-board obstacle detectors, such as bump sensors or similardevices, which register contact with an obstacle. Once contact is made,command routines can direct the autonomous vehicle to move in adirection away from the obstacle. These types of systems, which areuseful for obstacle avoidance, are limited in their ability to allow anautonomous vehicle to track its location within a room or other workingenvironment, Other systems, often used in conjunction with bump sensorsas described above, use an infrared or other detector to sense thepresence of nearby walls, obstacles, or other objects, and either followthe obstacle or direct the vehicle away from it. These systems, however,are also limited in their ability to allow an autonomous vehicle tonavigate effectively in a complex environment, as they only allow thevehicle to recognize when objects are in its immediate vicinity.

In more advanced navigation systems, an autonomous vehicle comprises aninfrared or other type of transmitter, which directs a series ofinfrared patterns in horizontal directions around the autonomousvehicle. These patterns can be detected by a stationary receiver placedat or near a boundary of the working space, for example on a wall. Amicroprocessor can use the information from signals generated by thereceiver to calculate where in the working space the autonomous vehicleis located at all times. Using such systems, the vehicle can navigatearound an entire area. These systems, however, are best employed inworking spaces where few objects are present that may interfere with thedispersed patterns of infrared signals.

Limitations of the above types of navigation systems are, at present, ahurdle to creating a highly independent autonomous vehicle that cannavigate in a complex environment.

SUMMARY

The present teachings provide a navigation control system for anautonomous vehicle. The system comprises a transmitter and an autonomousvehicle. The transmitter comprises an emitter for emitting at least onesignal, a power source for powering the emitter, a device for capturingwireless energy to charge the power source, and a printed circuit boardfor converting the captured wireless energy to a form for charging thepower source. The autonomous vehicle operates within a working area andcomprises a receiver for detecting the at least one signal emitted bythe emitter, and a processor for determining a relative location of theautonomous vehicle within the working area based on the signal emittedby the emitter.

The present teachings also provide a transmitter for use in a navigationcontrol system for an autonomous vehicle. The transmitter comprises anemitter for fitting at least one signal, a power source for powering theemitter, a device for capturing wireless energy to charge the powersource, and a printed circuit board for converting the captured wirelessenergy to a form for charging the power source.

The present teachings further provide a method for controllingnavigation of an autonomous vehicle within one or more work areas. Themethod comprises miffing one or more signals from a transmitter,receiving the one or more signals on the autonomous vehicle, poweringthe transmitter with a power as source, charging the power sourcewirelessly, localizing the autonomous vehicle with respect to thetransmitter, and navigating the autonomous vehicle within the one ormore work areas.

Additional objects and advantages of the present teachings will be setforth in part in the description which follows, and in part will beobvious from the description, or may be learned by practice of theteachings. The objects and advantages of the present teachings will berealized and attained by means of the elements and combinationsparticularly pointed out in the appended claims.

It is to be understood that both the foraging general description andthe following detailed description are exemplary and explanatory onlyand are not restrictive of the present teachings, as claimed.

The accompanying drawings, which are incorporated in and constitute apart of this specification, illustrate several embodiments of thepresent teachings and together with the description, serve to explainthe principles of the present teachings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic view of a navigation system for an autonomousvehicle in accordance with an exemplary embodiment of the presentteachings.

FIG. 2 is a schematic view of a navigation system for an autonomousvehicle in accordance with another exemplary embodiment of the presentteachings.

FIG. 3A is a side view of a stationary emitter in accordance with anexemplary embodiment of the present teachings.

FIG. 3B is a side view of a stationary emitter in accordance withanother exemplary embodiment of the present teachings.

FIG. 4A is a side view of an infrared receiver for an autonomous vehiclein accordance with an exemplary embodiment of the present teachings.

FIG. 4B is a top view of the infrared receiver of FIG. 4A.

FIG. 4C is a side view of an infrared receiver for an autonomous vehiclein accordance with another exemplary embodiment of the presentteachings.

FIG. 5A illustrates a control system for an infrared receiver for anautonomous vehicle in accordance with an exemplary embodiment of thepresent teachings.

FIG. 5B is a flowchart of a signal detection and localization program inaccordance with an exemplary embodiment of the present teachings.

FIG. 6 is a top view of a navigation system for an autonomous vehicle inaccordance with another exemplary embodiment of the present teachings.

FIGS. 7-14 are schematic circuit diagrams of infrared receivers andtransmitters for a navigation system in accordance with an exemplaryembodiment of the present teachings.

FIGS. 15A-15C illustrate side bottom, and end views, respectively, of anexemplary embodiment of a transmitter in accordance with the presentteachings.

FIGS. 16A-16C illustrate side, bottom, and end views, respectively, ofanother exemplary embodiment of a transmitter in accordance with thepresent teachings.

FIG. 17 illustrates the transmitter of FIGS. 15A-15C used in a doorway.

FIG. 18 also illustrates the transmitter of FIGS. 15A-15C used in adoorway.

FIGS. 19A-19C illustrate exemplary embodiments of setup screens on anexemplary remote control in accordance with the present teachings.

FIGS. 20A-20C illustrate exemplary embodiments of schedule screens on anexemplary remote control in accordance with the present teachings.

FIGS. 21A-21C illustrate exemplary embodiments of mode screen on anexemplary remote control in accordance with the present teachings.

FIG. 22 illustrates exemplary embodiments of a status screen on anexemplary remote in accordance with the present teachings.

FIG. 23 schematically illustrates an embodiment of a system inaccordance with the present teachings.

DESCRIPTION OF THE PRESENT TEACHINGS

Reference will now be made in detail to embodiments of the presentteachings, examples of which are illustrated in the accompanyingdrawings. Wherever possible, the same reference numbers will be usedthroughout the drawings to refer to the same or like parts.

In accordance with an exemplary implementation of the present teachings,FIG. 1 is a schematic view of a navigation system 10 for an autonomousvehicle such as a robotic cleaning device 12. The components of thesystem 10 include, in this embodiment, a transmitter 20, a charging orbase station 22, and an autonomous vehicle 12 that operates in a room orother similar working area 14. The working area 14 can be a floor of aroom, bounded at least in part by walls 16. Borders of a ceiling 18intersect the walls 16 and are remote from the working area 14. Thedepicted transmitter 20 includes two emitters 24A, 24B. In thisexemplary embodiment, the base station 22 includes an emitter 26 aswell. In various embodiments, any combination or quantity of emittersmay be used on the base station 22, or transmitter 20, or both. Theautonomous vehicle 12 can include an on-board microprocessor, power anddrive components, task-specific components (dirt sensors, vacuums,brushes, etc.), and at least one receiver, such as an infrared receiver28. The vehicle 12 may also include certain buttons, switches, etc. forprogramming the robot, or such instructions may be directed by a remotecontrol (see FIG. 18) or a personal computer (not shown). Depending onthe application, certain components may be removed from the disclosedsystem 10, or other components may be added.

For simplicity, this disclosure will describe vacuuming as ademonstrative task of the depicted robotic cleaning device 12. It willbe apparent, though, that the navigation system disclosed herein haswide applications across a variety of autonomous systems. For example,an autonomous vehicle may be used for floor waxing and polishing, floorscrubbing, ice resurfacing, sweeping and vacuuming, unfinished floorsanding, stain/paint application, ice melting and snow removal, grasscutting, etc. Any number of task-specific components may be required forsuch duties, and may each be incorporated into the autonomous vehicle,as necessary.

The transmitter 20 directs at least two infrared signals 22 a, 24 a fromemitters 24A and 24B to a surface remote from the working area 14 uponwhich the autonomous vehicle 12 operates. The depicted embodimentdirects the infrared signals 22 a, 24 a to the ceiling 18, but it mayalso direct the signals 22 a, 24 a to a portion of a wall 16 or to boththe walls 16 and ceiling 18. The signals 22 a, 24 a can be directed to avariety of points on the remote surface, but directing the signals ashigh as possible above the working area 14 can allow the signals 22 a,24 a to be more easily detected by the autonomous vehicle 12, becausethe field of view of the autonomous vehicle's receiver 28 is less likelyto be blocked by an obstacle (such as, for example, a high-backed chairor tall plant). In this disclosure, the regions of contact 22 b, 24 b ofthe signals 22 a 24 a on the remote surface will be referred to as“points,” regardless of the size of the intersection. For example, byusing a collimator in conjunction with the emitters (described below),the points of intersection 22 b, 24 b of the signals 22 a, 24 a can be afinite area with the signal strongest at approximately central points.

In certain embodiments of the transmitter 20, the signals 22 a, 24 a aredirected toward a ceiling 18, at two points 22 c, 24 c, forming a lineproximate and parallel to the wall 16 upon which the transmitter 20 islocated. Alternatively, and as depicted in FIG. 1, the signals 22 a, 24a can be directed away from the wall 16, at an angle of approximately 5°or more, to avoid interference with objects such as pictures secured toor hung from the wall 16. The signals 22 a, 24 a can be transmitted at aknown angle θ therebetween. In an exemplary embodiment, angle θ canequal approximately 30°, but other angles are contemplated by thepresent teachings. In accordance with certain embodiments, angle θ canbe set at the time of manufacture or user-defined based on particularapplications or other requirements. By setting the angle θ to a knownvalue, the distance S between the signals 22 a, 24 a at the point ofcontact 22 c, 24 c with ceiling 18 may be determined, provided theheights of the ceiling h₁, h₂ at the points of contact 22 c, 24 c areknown. When used on a flat ceiling 18, as depicted, h₁ equals h₂. In theembodiment depicted in FIG. 1, base station 22 emits a signal 26 a thatcan serve as art additional or optional signal for utilization by theautonomous vehicle 12. Signal 26 a is directed toward a wall 16, so thatthe point of contact 26 b is high enough to avoid objects that mayobstruct the autonomous vehicle's field of view. A central point 28 c(or laser point) of the point of contact 26 b contacts the 16 at heighth3.

As the autonomous vehicle 12 moves within a working area 14, it detectsthe signals 22 a, 24 a emitted by the transmitter 20 as energy bouncingor reflecting off of the diffuse ceiling surface 18. In an iterativeembodiment, visible points can be used in place of infrared points. Acamera onboard the autonomous vehicle can replace the infrared receiverin detecting either infrared or visible points. The autonomous vehicle'smicroprocessor can convert the signals 22 a, 24 a sensed by the receiver28 into bearings from the robot 12 to the signals 22 e, 24 a. Themicroprocessor can then calculate representative elevation angles ε₁, ε₂and azimuths α₁, α₂ of the signals to determine the location of theautonomous vehicle 12 within the working area 14. In this embodiment,the azimuths α₁, α₂ are measured using a “forward” direction of movementM of the autonomous vehicle 12 as a datum, but any suitable datum can beused. By calculating the elevation angle and azimuth from the autonomousvehicle 12 to the two signals 22 a, 24 a, the autonomous vehicle 12 canlocate itself within a working area with improved accuracy.

FIG. 2 depicts another exemplary embodiment of a navigation system 110for an autonomous vehicle 112. In the illustrated exemplary embodiment,an autonomous vehicle 112 moves in a working area having a floor 114. Atransmitter 120 can be mounted at a top frame of a doorway 132 betweentwo rooms 136, 138. Similar to the embodiment depicted in FIG. 1, thetransmitter 120 is installed at a known distance h₄ above the floor 114.In alternative embodiments, the transmitter 120 can be installed at theheight of the ceiling 118. The transmitter 120 can be recessed withinthe door frame 130 or ceiling 118 to reduce its profile and limit itsimpact on architectural aesthetics at a room. Additionally, thetransmitter 120 can be disguised to resemble a cover plate for asprinkler head, speaker, or other device.

The transmitter 120 emits two signals 122 a, 124 a (depicted graphicallyby a plurality of arrows) into the two rooms 136, 138, respectively. Thesignals 122 a, 124 a can be configured to not overlap each other. thusproviding a distinct signal on each side of the door centerline 130. Inother embodiments, an overlap of the signals 122 a, 124 a can bedesirable. The autonomous vehicle 112 includes a receiver 128 having afield of vision 134. The emitted signals 122 a, 124 a can be detected bythe receiver 128 when the autonomous vehicle's field of vision 134intersects the signals 122 a, 124 a. Similar to the embodiment of FIG.1, the autonomous vehicle can calculate the azimuth and elevation to thetransmitter 120 to determine its relative location. Similar to theembodiment described above, by detecting only one signal, the autonomousvehicle 112 can calculate a bearing to the transmitter 120. Accordingly,the transmitter 120 functions as a beacon for the autonomous vehicle 112to follow and, if the signal is coded, the autonomous vehicle 112 candetermine which room of a number of rooms it is located in, based on thecoded signal. The autonomous vehicle 112 is thus able to determine itsrelative location, on a room-by-room basis, as opposed to determiningits location within a room. Exemplary embodiments of a doorway-basedtransmitter are described in more detail with reference to FIGS. 15-18.

FIG. 3A shows a transmitter 20 in accordance with certain embodiments ofthe present teachings. The depicted transmitter 20 receives power from awall outlet 40 for convenience and unobtrusiveness, but one skilled inthe art will appreciate that transmitters can be powered by means otherthan a wall outlet. For example, the transmitter can be placed anywherein a room, provided it has an available power source. For example,battery-powered transmitters are particularly versatile, because theycan be located remote from a wall outlet. Such battery-operatedtransmitters can be unobtrusively located above window or door frames,or on top of tall furniture such as dressers or bookshelves.

In accordance with various embodiments of the present teachings, thetransmitter can include a visible signal option (not shown), alignedwith the emitted signals, allowing a user to direct the signals toparticular locations. In accordance with the present teachings, morethan one transmitter maybe used. Such a system could includecommunication capability between the various transmitters, for exampleto ensure that only one signal or a subset of signals is emitted at anygiven time.

A battery-powered transmitter located above a window or door frame cannot only permit the autonomous vehicle to localize within a map,coordinate system, or cell grid relative to the transmitter, but canalso localize the transmitter within the same map, coordinate system, orcell grid, thereby localizing the window or door frame. Localization ofan autonomous vehicle within a working environment is described indetail in U.S. Patent Publication No. 2008/0294288, filed Nov. 27, 2008,the entire disclosure of which is incorporated herein by reference. Inthe case of a door frame, the door is ordinarily the passage by whichthe autonomous vehicle navigates from room to room. The transmitterillustrated in FIG. 3A, which can project points upward onto a wall orceiling, can be battery operated. A transmitter as illustrated in FIGS.3B-3D can be placed above or at the top of a door (e.g., more than sixfeet high, where household power may be unavailable) and can alsobenefit from battery operation (see below).

The exemplary embodiment of a transmitter 20 illustrated in FIG. 3Aincludes a housing 42 constructed of, for example, a plastic or likematerial. In this figure, the transmitter is shown cut-away above theline L so that the emitters can be seen. The transmitter 20 can includea power receptacle 44, allowing the outlet used by the transmitter 20 toremain available for other uses. The transmitter 20 includes twoemitters 24A, 24B, set within the housing 42. Alternatively, theemitters 24A, 24B can be flush with or extend beyond the housing 42.Setting the emitters 24A, 24B within the housing 42 allows the signals22 a, 24 a to be directed by utilizing collimators 22 e, 24 e. Thecollimators 22 e, 24 e can be formed within the housing 42 Cr can bediscreet components within the housing 42. Alternatively, thecollimators 22 e, 24 e can be secured to the outside of the housing 42.In alterative embodiments, lenses 22 d, 24 d can be included, with orwithout collimators 22 e, 24 e, to focus and direct the signals 22 a, 24a. These basic manufacturing considerations can also be adapted foremitters located on charging or base stations. One or more emitters on abase station can serve as an additional point of navigation for theautonomous vehicle within the room, or may simply aid the autonomousvehicle in locating the base station.

FIG. 3B depicts an embodiment of a transmitter 120 for use, for example,with the navigation system 110 depicted in FIG. 2. The transmitter 120is secured to the underside of an upper cross member of the door frame132, but can also be recessed therein or secured to or recessed in aceiling 118. The transmitter 120 includes two emitters 122, 124. Otherembodiments of the transmitter 120 can include more than two emitters ora single emitter. By utilizing two emitters, the transmitter 120 candirect signals into two different rooms, on either side of thecenterline 130 of the door frame 132. This can allow an autonomousvehicle to distinguish which room it is located in.

In accordance with various embodiments of the present teachings, morethan two emitters can be utilized with collimators 22 e, 24 e, 122 e,124 e, to distinguish different areas within a room. Such aconfiguration allows the autonomous vehicle to sense its relativelocation within a room and adjust its cleaning behavior accordingly. Forexample, a signal could mark an area of the room that an autonomousvehicle would likely get stuck in. The signal could allow an autonomousvehicle to recognize the area and accordingly not enter it, even thoughit might otherwise be able to do so unimpeded. Alternatively, or inaddition, different signals could mark areas that require differentcleaning behaviors (e.g., due to carpeting or wood floors, high trafficareas, etc.).

Turning back to FIG. 3B the emitters 122 124 can be installed flush withor extend beyond the housing 142. Setting the emitters 122, 124 withinthe housing 142 allows the signals 122 a, 124 a to be directed byutilizing collimators 122 e, 124 e. The collimators 122 e, 124 e allowthe signals 122 a, 124 a to be directed to two sides of a centerline 130of a doorframe 132, without any signal overlap, if so desired. Thecollimators 122 e, 124 e can be formed within the housing 142 or can bediscreet components within the housing 142. Alternatively, thecollimators 122 e, 124 e can be secured to the outside of the housing142. In alterative embodiments, lenses 122 d, 124 d may be included,with or without collimators 122 e, 124 e, to focus and direct thesignals 122 a, 124 a.

In various embodiments of the present teachings, each signal (regardlessof the emitter's location or the number of signals) can be modulated at10 kHz and coded with an 5-bit code serving as a unique signalidentifier, preventing the autonomous vehicle from confusing one signalor point with another. Accordingly, more than two uniquely encodedsignals can be employed to increase the accuracy of the autonomousvehicle's calculations regarding its location within a working area. Asnoted above, using only one emitter allows an autonomous vehicle to takea heading based on that signal. Using two or more signals can allow theautonomous vehicle to continue navigating if fewer than all of thesignals are detected (either due to failure of a signal transmission orthe autonomous vehicle moving to a location where fewer than all of thesignals are visible).

In certain embodiments, the transmitter can pulse the coded signals asfollows. After an initial synchronization pulse, a first signal at 10kHz is emitted for 100 ms. This can provide a sufficient time for theautonomous vehicle's receiver and processor to calculate azimuth andelevation angles, as discussed in detail below. So that the autonomousvehicle can determine which signal is being received, the transmittercan pulse a series of five bits, each for 10 ms. The five bits includetwo start bits, for example a zero and a one, followed by a unique threebit identifier to identify that particular signal or point. After a 100ms delay, the transmitter repeats the sequence for the second signal orpoint. By changing the modulation frequency and/or the identifier, thesecond signal or point can be uniquely distinguished from the first. Anynumber of unique signals can be transmitted and identified in thismanner. After the series of signals are transmitted, the transmitter canwait a substantially longer period of time, for example on the order ofone to two seconds, before repeating the transmitting sequence, startingagain with the first signal. The length of time for each transmission ismerely exemplary, and may be varied based on a particular application,device, etc. As stated above the signals can be modulated at the same ordifferent frequencies.

FIG. 4A depicts a side view of an exemplary receiver 228 that is surfacemounted on a housing 212 of an autonomous vehicle. FIG. 4B is a top viewof the same receiver 228. The receiver 228 can include an outer shell orhousing 244 comprising a generally translucent or transparent,high-impact plastic or like material. Four photodiodes 246 a, 246 b, 246c, and 246 d can be installed in an orientation in the housing 244generally corresponding to four adjacent sides of a cube. Accordingly,each photodiode can be generally perpendicular to the photodiodes oneither side of it and parallel to the photodiode opposite it. In certainembodiments, a fifth photodiode 246 e can be located generally above theplane of orientation of photodiodes 246 a-246 d. At least onephotodiode, in this case photodiode 246 a, is oriented toward adirection of forward movement M of the robot. The photodiodes can beconnected via control wiring and other components to the autonomousvehicles microprocessor and related systems. Installing a receiver 226on top of the housing 212 can provide the autonomous vehicle with a widefield of view. As depicted, the field of view δ1 for ahorizontally-oriented photodiode 246 e is extremely wide. Depending onthe sensitivity of the photodiode 246 e, the thickness or translucenceof the plastic, and other factors, the field of view δ1 may approach orexceed 180°. Similarly, due to the orientation of photodiodes 246 a-246d, their field of view δ2 approaches near vertical in an upwarddirection from the autonomous vehicle's housing 212 and is limited belowonly by the autonomous vehicle's housing 212. There can be an overlapbetween the fields of view 61 and 62 in the longitudinal plane, asdepicted in FIG. 4B.

As illustrated in FIG. 4A, there can be overlap between the fields ofview 31 and 62, allowing the autonomous vehicle to detect signals in itsoperating area. The overlap creates a total field of view for thereceiver that approaches the entire volume of the room above the robothousing. Accordingly, this embodiment of the receiver 212, iswell-suited to the exemplary embodiment of the navigation systemdepicted and described in FIG. 2, wherein a signal is projected into anentire room. Of course, this receiver 228 could also be used with thesystem depicted in FIG. 1. Although installing the receiver closer to orabove a top surface of the autonomous vehicle can provide for a widerrange of view, this configuration increases a height of the autonomousvehicle slightly and can limit autonomous vehicle travel beneath certainobstacles such as couches, low tables, or the like.

FIG. 4C depicts an exemplary embodiment of the receiver 328 installedbelow a surface of the autonomous vehicle housing 312. The photodiodes346 a-346 e (as a group referred to as 346) can be installed in a void350 or other cavity below the surface of the autonomous vehicle housing312. A translucent or transparent plastic cover 312 a can be fitted overthe photodiodes 346. The cover 31 2 a can be secured to the housing 312,for example, with strews, press-fit connections, or other connectors.Alternatively, the cover 312 a can be set in place without connectors,allowing easier access the photodiodes 346 for service or replacement.This lower profile version reduces or eliminates the risk associatedwith a surface mounted receiver getting stuck below obstacles (asdescribed above).

The construction of the receiver 328 can be similar to that of FIG. 4A.Four of the photodiode 346 a-348 d can be installed orthogonal to eachother, facing a predefined direction on the autonomous vehicle (e.g.,front, back, right and left). The fifth photodiode 346 e can beinstalled orthogonal to the other four photodiodes, facing directly upfrom a top of the autonomous vehicle. Because the photodiodes 346 areset within the housing 312, the receiver's overall field of view δ3 canbe limited to a certain degree. In this embodiment, δ3 equalsapproximately 120°. The field of view δ3 can be wider or narrowerdepending on the depth of installation below the surface of theautonomous vehicle housing 312. Alternatively, the field of view δ3 canbe modified by utilizing a cover 312 a having particular effects onsignal transmission, such as a fish-eye lens or the like.

FIG. 5A illustrates an exemplary embodiment of a control schematic 560for a receiver 528. The receiver 528 can include a number of independentphotodiodes 546 a-546 e (as a group referred to as 546), pre-amplifiedand multiplexed into a single microprocessor 562. As described above,four of the photodiodes 546 a-546 d can be installed orthogonal to eachother, facing a predefined direction on the autonomous vehicle (e.g.front, back, right, and left). A fifth photodiode 546 e can be installedorthogonal to the other four, facing directly up from the top of therobot. Once a reflected signal is received by a photodiode 546, thereceiver 528 determines the frequency of modulation of the signal, theidentity sequence, if any, and the envelope of received energy (i.e.,the demodulation of energy). These values can be sent to microprocessor562, which can calculate the location of the autonomous vehicle relativeto the signals and the identities of the signals. Additionally, if onlya single point is detected by the receiver 528 (if for example, therobot's view of the second signal is obstructed), the autonomous vehiclecan use this point as a heading. By following this heading, theautonomous vehicle can move within the work area until a second point isdetected.

In operation, a receiver (e.g., an infrared receiver) can first measurethe “noise floor” of the autonomous vehicle's environment, comprisingthe amount of energy (e.g., infrared energy) present in the autonomousvehicle's environment, which it sets as the threshold value. This valuecan represent an average of the values for each photodiode. Anysubsequent measurement above this threshold value can trigger an event(e.g., a calculation of point azimuth and elevation). The receiver canthen measure the modulation frequency again, searching for an expectedincrease at 10 kHz (i.e., the frequency of the initial synchronizationsignal transmitted by the transmitter). If a 10 kHz frequency increaseis detected, the autonomous vehicle recognizes the increase as anemitted navigation signal. The autonomous vehicle can then measure theamplitude of the reflected point on all five photodiodes to determine anaverage value. This value can then be compared to a list of signalfrequencies to determine which of the signals has been detected.Alternatively, any detected identity sequence associated with the signalcan be compared to a list of transmitter codes or signal IDs stored in alookup table in the autonomous vehicle's processor memory.

The on-board microprocessor can use the amplitude value to determine theazimuth and elevation of the received signals, which it can then use todetermine its location within a working area. To determine the azimuth,the microprocessor enters the values of the two strongest readings fromthe four side photodiodes into an algorithm. The algorithm takes theratio of these two readings to determine the azimuth angle. For example,if the two strongest readings from two photodiodes are equal, thealgorithm recognizes that the point is located at an azimuth angle thatis directly between the two photodiodes (i.e., at 45°). In a similaralgorithm, the amplitude value measured from the strongest sidephotodiode and the amplitude value measured from the top-facingphotodiode value are used to determine the elevation of the signal.These values can be stored in the autonomous vehicle's memory for futurereference.

After the receiver has detected at least two points, and determines theazimuth and elevation of each point, it determines its location withinthe working space. A triangulation algorithm based on the known ceilingheight and the azimuth and elevation of the two detected points allowsthe processor to determine where in the working space the autonomousvehicle is located. Over time, the values of elevation and azimuthbetween each coded point and specific locations of the autonomousvehicle within the workspace can be stored in the autonomous vehicle'smemory, creating a map of the environment in which the autonomousvehicle operates.

In various embodiments, a navigation system 200 as depicted in FIG. 5Buses an angle-based localization system. Values corresponding toelevation and azimuth are determined by synchronously comparing averageamplitudes from the number of detectors arranged on the robot. Of thefive detectors, four are arranged in a plane end are angularly spaced by90° increments. The fifth detector is in the center of theaforementioned four-detector array and aimed so that it is orthogonal tothe plane in which the other detectors lie, directed vertically from theautonomous vehicle. Together, this five-element array can have a full ornear-full hemispherical field of view.

In the embodiment depicted in FIG. 5B, all five detectors monitor foramplitude (Step 705) until an amplitude that crosses a preset thresholdis detected (Step 710). After the amplitude on any detector crosses thepreset detection threshold, the frequency of the signal on the strongestdetector is measured and compared against known transmit frequencies(Step 715). If the measured frequency is one of the known transmitfrequencies (Step 720), the next step in the detection process can beexecuted. If the signal is not a known transmit frequency, the detectionprocess can be aborted (Step 725) and the signal detected can bedeclared to be “out of band.” Once an “in band” frequency is detected, atime-averaged amplitude for each photo detector can be measured,converted to a binary number, and stored for later processing in amicroprocessor memory (Step 730). Upon storing the five numerical values(one for each photodiode), the azimuth angle can be determined.

Of the four detectors that reside in a single plane, the values of thetwo strongest signals detected are used to form a ratio to determine theazimuth angle (Step 735). The ratio of second-strongest signal over thestrongest signal is either compared to a look-up table or inserted intoa mathematical equation to determine an azimuth angle output. Both thelock-up table and the equation represent the overlap of the receivedsensitivity patterns of two orthogonal detectors with known sensorresponses. In this embodiment, the photo detector output is modeled as afourth-order Gaussian response to angle off of “boresight,” a term thatgenerality refers to a vector that is orthogonal to the semiconductorthe in the detector package.

To calculate elevation, the strongest signal from azimuth calculation(i.e., the denominator of the ratio) must first be normalized, as if itwere on boresight at the respective detector (Step 740). For example, ifthe azimuth has been determined to be 10° off of boresight from a givendetector, that 10° angle is entered into a look-up table or equationthat describes the sensor response of any single photo detector. At zerodegrees, the output of this look-up table/equation would be 1,00000. Asthe angle deviates from zero degrees the output drops to some fractionof 1.00000 (the normalized value at boresight). For example, if a valueof 10° is entered into the equation, the output of this operation canbe, for example. 0.09000. The denominator of the azimuth ratio can thenbe divided by this fractional value in order to scale up, or “normalize”that value to what it would be if the azimuth were actually zerodegrees. This normalized value can then be stored in memory andelevation can be determined therefrom.

To calculate elevation, the normalized output from the previous step isused to produce a new ratio with the output from the upward-looking(fifth) detector, so that the numerator is the second-strongest of thetwo values and the denominator is the strongest of the two values (Step745). This ratio is then entered into the same look-up table or equationfrom the step above (used to calculate azimuth), thus outputting anelevation angle.

The benefits of this type of navigation system can be numerous. As theautonomous vehicle moves about a working area, measuring the azimuth andelevation of the various points detected it can create a map of thearea, thus determining its location within a given space. With thisinformation it can fuse data from all of its on-board sensors andimprove cleaning or other task efficiency. One way it can do this is tocreate a map where the high-traffic areas in a house or other buildingare located (as indicated by readings from the dirt sensor, forexample). The autonomous vehicle would then clean the areas itidentified as high traffic (and therefore, often dirty) each time itpasses over that area, whether directed to or not. The autonomousvehicle may also improve its cleaning function by merging the outputfrom the wheel drop, stasis, bumper, and wall-following sensors toroughly mark areas of entrapment, or where large obstacles exist, sothat those areas can potentially be avoided in future runs.

In accordance with various embodiments of the present teachings, anothermethod of improving cleaning efficiency involves selectively programmingthe autonomous vehicle to clean particular areas, as detailed below. Forexample, a personal computer or remote control may be used to controlthe autonomous vehicle. Although the autonomous vehicle can operatewithout operator intervention, an operator can initially set up theautonomous vehicle, or can direct the autonomous vehicle to operate inparticular areas or at particular times. For example, by using more thanone transmitter in various rooms on one floor of a house, an operatormay be able to direct the autonomous vehicle to clean specific rooms ina particular order and/or at a specific time. The operator could select,in a control program field of a computer program for example, the livingroom, family room, bathroom, and kitchen areas for cleaning. A remotecontrol for use in accordance with the present teachings is described inmore detail with respect to FIGS. 19-22.

Once commanded (either immediately or on a predefined schedule), theautonomous vehicle can be signaled to begin its cleaning cycle. Theautonomous vehicle undocks from its base/charging station and beginscleaning the closest or first room on the programmed list. It canrecognize this room and can differentiate it by the coded group ofinfrared points (e.g. on a ceiling of the room) or the coded signalemitted in the room. After the first room is cleaned, the autonomousvehicle can, for example, check its level of power and return to itscharger for additional charging if needed. In accordance with certainembodiments, in order to return to the charger the autonomous vehiclecan follow the point or points on the ceiling back to the base station.Alternatively, the autonomous vehicle can use a known docking behavior.After charging is complete, the autonomous vehicle can traverse roughlyback to the place left off and resume cleaning. This sequence of eventscontinues until all of the programmed rooms have been cleaned.Alternatively, the selection of particular areas to clean could be, forexample, made by remote control or by pressing buttons on a controlpanel located on the base station. By using a personal computer,however, multiple transmitters could communicate with each other andwith the base station via power lines using a known communicationtechnology.

An alternative embodiment of the present teachings is depicted in FIG.6, wherein an autonomous vehicle uses a number of signals for headingsto move from room to room. The autonomous vehicle 612 is moving in adirection M within room A when its power level drops below apredetermined level, requiring its return to a base charging station622. Upon crossing the predetermined power level, the autonomousvehicle's receiver 628 searches for a signal from a nearby emitter. Asthe vehicle is located in room A, it detects the signal 622 a emittedfrom transmitter 620 a and, using the signal 622 a as a heading, movesdirectly for that signal 622 a.

Alternatively, the autonomous vehicle 612 can emit its own coded pulse,to determine if any transmitters are in the area. This coded pulse could“awaken” sleeping or otherwise dormant transmitters, which would thenbegin their own emission cycle. Alternatively, the pulse can be anaudible or visual signal such as a distinct beep, buzz, or visualstrobe. Some pulses need not be within the field of view of thetransmitter.

The robot 612 will continue to move toward signal 622 a until one ofseveral events happens at or near doorway 632 a. In a first event, theautonomous vehicle may determine, based on readings from itsphotodiodes, that it is directly under the transmitter 620 a. In asecond event, the autonomous vehicle 612 may sense a second signal 624a, which may overlap the first detected signal 622 a. This could occurif the configuration of the emitters, collimators, etc., as described inmore detail above, provides overlapping signal patterns between signals622 a and 624 a. In a third event, autonomous vehicle 612 can sense asignal from an entirely different transmitter, in this case signal 622 bfrom transmitter 620 b. Other events are also contemplated, as suitablefor a particular application. The occurrence of an event presents theautonomous vehicle 612 with any number of behavioral, functional, orother options. For example, each coded signal may serve as a uniquemarker for a different working space. Upon detecting the unique markerassociated with a particular working space, the autonomous vehicle mayalter its cleaning function. Thus, if room A is carpeted but room B isuncarpeted, the autonomous vehicle can adjust its cleaning as it movesfrom roof A to room B. Upon detecting a second signal (in this case,signal 622 b) the autonomous vehicle can, in certain embodiments,completely disregard the first signal 622 a received 3 when its returnto the base station 622 began. Using new signal 622 b as a heading, itbegins moving toward that signal 622 b. The autonomous vehicle 612 can,in certain embodiments, check its battery level at each event, storingthat value in its microprocessor. Over time, the autonomous vehicle canthereby create a table of battery levels at each event (and batterylevel change from event to event), and be able to accurately determineprecise battery power remaining at each transmitter location.

Once the autonomous vehicle is traversing room B (shown in phantom as612′), it will eventually determine, based on battery level, time, orother factors, to follow the heading provided by signal 622 b, andcontinue its return to its base station 622. The autonomous vehicle 612can follow the heading until an event occurs at or near doorway 632 b.Again the event can be detecting a strength of signal 622 b, indicatingthat the autonomous vehicle is directly below the transmitter, detectingan overlap signal from 624 b, or detecting a new signal 622 c. Theautonomous vehicle 612 can again perform any of the behaviors describedabove: check and store its battery level; change cleaningcharacteristics; etc.

Once in room C, the autonomous vehicle can begin following the headingprovided by signal 622 c. At or near the doorway 632 c to room D, anevent may direct the autonomous vehicle to perform any number ofbehaviors. Alternatively, the autonomous vehicle can move directly tocharging station 622, guided by emitted signal 626 or another signal orprogram.

During its return to the base station, as the autonomous vehicle 612moves from room A to room B to room C and so on, it detects and storesinformation about each coded signal that it detects along its route. Bystoring this information, the autonomous vehicle can create a map, usingthe coded signals as guideposts, allowing it to return to its startinglocation in the future. After charging, the autonomous vehicle canreturn to the room it was working in prior to returning to its base bycomparing the detected signals and their strengths to the storedinformation.

FIGS. 7-9 depict schematic circuit representations for exemplaryembodiments of various components of an infrared signal transmitter,namely an AC-DC converter, a microcontroller and support circuitry, andLED drivers. More specifically, FIG. 7 illustrates an electronic circuitthat takes 120 VAC 160 Hz line voltage and converts it to a regulated +5VDC supply. This supply can be used to power the microcontroller andassociated circuitry of the transmitter depicted in FIG. 8. In additionto power conversion, this circuit can also provide an isolated digitallogic signal to the microcontroller, whenever a “zero-crossing” in theAC line input is detected.

FIG. 8 illustrates a transmitter microcontroller and support circuitry(i.e., a clock oscillator and an in-circuit serial programming port). Inaddition, there is a circuit that allows a user-initiated button pressto protect visible light from a pair of LEDs, co-located with a pair ofIR LEDs, onto a remote surface for the purpose of assisting the user inaiming the infrared signal points.

FIG. 9 illustrates two channels of an IR LED driver. Each driver cancontrol a preset constant current into a single IR LED, which can thenemit near-infrared light that can be collimated by an external lens andprojected onto the remote surface. Each IR LED can be modulated andpulse-coded independently of the other. This allows the microcontrollerin the autonomous vehicle to discern between the different transmittersignals, to determine which detected signal is which.

FIGS. 10-14 depict schematic circuit representations in accordance withcertain embodiments of various components of a vehicle-mounted infraredreceiver, namely DC-DC linear power converters, a five channelpreamplifier, a multiplexer and programmable tuned amplifier, detectors,and a microcontroller and associated peripherals. More specifically,FIG. 10 depicts two independent linear voltage regulators. One of theregulation circuits can be switched ON-OFF via a microcontroller toconserve battery power during a sleep mode.

FIG. 11 depicts five independent preamplifiers that can convertrespective photodiode output currents into voltages of much largermagnitudes. Each preamplifier is built using an operational amplifier ina transimpedance topology. This allows the preamplifiers to beconfigured with low noise. Also, there is an active feedback circuitthat is used to null large photodiode current offsets caused by exposureof the circuit to sunlight and other strong low-frequency light sources.

FIG. 12 illustrates an exemplary multiplexer and programmable tunedamplifier for the receiver. This circuitry can be segregated into threefunctional blocks. The first block is a multiplexer thatreceives'signals from the five photodiode preamplifiers and outputs oneof the signals to a programmable attenuator, as ended by the receiver'smicrocontroller. The second block is a programmable attenuator that canbe used to reduce the overall receiver gain, to deal with the largedynamic range of received signals. As depicted herein, there are twodigital inputs from the microcontroller, which permits four discretegain levels to be selected. The third block is a tuned, band-passamplifier that can provide the hulk of the voltage amplification tosignals that fall within the circuit's pass band.

FIG. 13 depicts an exemplary embodiment of two detectors that can beused in the receiver. The first detector is a rectifying, envelopedetector with integral voltage gain, and can be used to strip modulationfrequency and provide a signal envelope to the microcontroller's analogto-digital converter. The signal envelope can be used the bymicrocontroller to determine the magnitude of the received signal. Thesecond detector is a voltage comparator, which can be used to “squareup” received pulses and convert them to a CMOS logic level, therebyallowing the microcontroller to extract digital data from the receivedsignals.

Lastly, FIG. 14 illustrates the microcontroller and its peripherals. Theperipherals can include a clock oscillator, ICSP port, voltagesupervisor/reset generator, and RS-232 level serial port for interfacingwith a host personal computer or main robot processor.

Accordingly, the navigation system can be operationally robust andadapted to compensate for variances in infrared energy. For example, ifthe autonomous vehicle is operating in an environment with high baseinfrared readings (e.g., a space with a large number of fluorescentlighting fixtures or windows that allow entry of sunlight), theautonomous vehicle can distinguish the infrared signals generated by thetransmitter from the infrared noise present in the space. Similarly, thereceiver can distinguish between other off-band signals such as infraredremote controls. In such cases, establishing an initial threshold valueof infrared energy and emitting a predefined, known, modulated infraredsignal from the transmitter overcomes these environmental disturbances.Additionally, the transmitter can be tuned to emit a sufficiently stronginfrared signal to accommodate surfaces with varied reflectivity.

FIGS. 15A-15C illustrate side, bottom, and end views, respectively, ofan exemplary embodiment of a transmitter 200 having a thin rectangularhousing and configured for placement in a variety of locations includinga top surface of a doorway as illustrated in FIGS. 2, 6, 17, and 18. Inthe illustrated embodiment, an emitter 222, 224 is located adjacent eachedge E_(L), E_(R) of the transmitter 200. In accordance with certainembodiments of the present teachings, each emitter can comprise a lens222 d, 224 d as described above to focus and direct the emitted signal.The present teachings also contemplate the transmitter 200 comprising athird emitter 226 With a lens 226 d to focus and direct the emittedsignal. The illustrated transmitter 200 also comprises a battery 230 anda printed circuit beard 240. As discussed above, the battery 230 canprovide power to the transmitter 200 while allowing the transmitter 200to be located without regard to proximity of power supplies such as walloutlets. Other portable power sources such as capacitors can also beused instead of, or in addition to, the battery. The printed circuitboard 240 can be employed to modulate and code the emitted signals, andto provide power conversion for wirelessly charging the battery 230 orother power source. An antenna 250 can be utilized to intercept fieldsfor conversion to current for wirelessly charging the battery, asdescribed in more detail below.

Wireless charging in accordance with the present teachings can comprise,for example, RF scavenging or magnetoresonance. Wireless charging via RFscavenging can be accomplished as disclosed in U.S. Patent PublicationNo. 2009/0102296, the entire disclosure of which is incorporated hereinby reference. The antenna 250 (e.g., a RF wireless communicationantenna) can facilitate both energy harvesting and wirelesscommunication for the transmitter 200 and, to facilitate energyharvesting, can harvest RF energy from a variety of sources including,for instance, medium frequency AM radio broadcast, very high frequency(VHF) FM radio broadcast, cellular base stations, wireless data accesspoints. etc. The energy can be harvested from that naturally availablein the environment (work area) or can be broadcast by a source such asan RF signal emitter on the autonomous vehicle or on another device suchas a base station or a dedicated emitter. FIG. 23 schematicallyillustrates an embodiment of the present teachings where an autonomousvehicle 12 includes a RF 1 emitter 360 that directs an RF signal towardthe transmitter 200 for harvesting to ensure adequate RF energy forrecharging the battery 230 or other power source. The printed circuitboard 240 can serve to convert the harvested RF energy into a usableform, for example AC voltage or DC voltage. The printed circuit board240 can also regulate the converted power.

Certain embodiments of the present teachings contemplate wirelesscharging via strongly coupled magnetic resonances, or magnetoresonance.Such wireless charging is described in detail in Kurs, et al., WirelessPower Transfer via Strongly Coupled Magnetic Resonances, Science, Vol.317, pp. 83-86 (Jul. 6, 2008), the entire disclosure of which isincorporated herein by reference. For wireless charging viamagnetoresonance, the antenna 250 can comprise, for example, a capturecoil that can capture and convert magnetic energy to AC voltage or DCvoltage. The magnetic energy captured by the capture coil can besupplied by a power source such as a highly resonant magnetic source.The power source can be located, for example, on the autonomous vehicle(in a scenario such as that illustrated in FIG. 23), on a dedicateddevice, or on a base station for the autonomous vehicle.

One skilled in the art will appreciate that the transmitter 200 canderive its power from a source other than a battery, for example from awall plug or by direct connection to a building's power supply. Also,the emitters can have differing locations on the transmitter, and neednot be combined with a lens as illustrated. The size of the transmittercan vary in accordance with functional considerations (e.g., being largeenough to house its components) as well as aesthetic considerations(e.g., minimizing size to be less obtrusive).

FIGS. 16A-16C illustrate side, bottom, and end views, respectively, ofanother exemplary embodiment of a transmitter 300 having a thinrectangular housing and configured for placement in a variety oflocations including a top surface of a doorway as illustrated in FIGS.2, 6, 17, and 18. In the illustrated embodiment, an emitter 322, 324 islocated adjacent each edge of the transmitter 300. In accordance withcertain embodiments of the present teachings, each emitter can comprisea collimator 322 e, 324 e and a lens 324 d (see FIG. 16C) as describedabove to focus and direct the emitted signal. Although a third emitteris not illustrated in this embodiment, the transmitter can comprise atleast one additional emitter and can employ a lens and/or collimatorthereon to focus and direct the emitted signal. The illustratedexemplary transmitter 300 also comprises a battery 330 and a printedcircuit board 340. As discussed above, the battery 330 can provide powerto the transmitter 300 while allowing the transmitter 300 to be locatedwithout regard to proximity of power supplies such as wall outlets. Theprinted circuit board 340 can be employed to modulate and code theemitted signals, and to provide power conversion for wirelessly chargingthe battery 330 or other power source. An antenna 350 can be utilized tointercept magnetic or RF fields for conversion to current for wirelesslycharging the battery 330, as described above with respect to FIG. 15.

One skilled in the art will appreciate that the transmitter 300 canderive its power from a source other than a battery, for example from awall plug or by direct connection to a building's power supply. Also,the emitters can have differing locations on the transmitter, and neednot be combined with a collimator and/or a lens as illustrated. The sizeof the transmitter can vary in accordance with functional considerations(e.g., being large enough to house its components) as well as aestheticconsiderations (e.g., minimizing size to be less obtrusive).

FIG. 17 illustrates a transmitter 200 mounted on a top surface T of adoorway DW or other passage between two areas. In the illustratedembodiment, because the transmitter 200 is placed at a high positionwithin the room or work area, the emitted signals should not be directedupward toward the ceiling and instead should be directed toward theportion of the room through which the autonomous vehicle 12 travels. Inaccordance with various embodiments, the emitted signals can be codedand modulated as discussed above, so that the autonomous vehicle 12 canrecognize the transmitter for localization and/or navigation purposes.In addition, in accordance with certain embodiments, the emitted signalscan include information for the autonomous vehicle 12, such asinformation instructing the autonomous vehicle to adjust its cleaningbehavior.

In embodiments of the present teachings employing more than twoemitters, the signals can be utilized, e.g., with collimators or lenses,to distinguish different areas within a room. Such a configurationallows the autonomous vehicle 12 to sense its relative location within aroom and adjust its cleaning behavior accordingly. For example, a signalcould mark an area of the room that an autonomous vehicle would likelyget stuck in. The signal could allow an autonomous vehicle to recognizethe area and accordingly not enter it, even though it might otherwise beable to do unimpeded. Alternatively or additionally, different signalscould mark areas that require different cleaning behaviors (e.g., due tocarpeting or wood floors, high traffic areas, etc.).

The transmitters 200, 300 as illustrated in FIGS. 15A-15C and FIGS.16A-16C, respectively, can function in a manner similar to transmitter120 in FIG. 2, as described above, with the additional emitter(s)allowing more functionality, as described above, such as indicatingareas requiring different cleaning behaviors. The transmitters 200, 300can also function in a manner similar to the transmitters illustrated inFIG. 6, and particularly those located within the doorway/roomtransitions in FIG. 6.

FIG. 18 illustrates the autonomous vehicle of FIG. 17 passing through adoorway DW, and additionally illustrates an exemplary embodiment of thepresent teachings utilizing a remote control 370 to communicate with theautonomous vehicle 12 and/or the transmitter 200. An exemplaryembodiment of a remote control 370 is disclosed in more detail in FIGS.19A-22.

As illustrated in FIGS. 19A-19C, the remote control 370 can include oneor more power buttons 340 for powering ON/OFF the remote control 370,the transmitter 200, 300, and/or the autonomy a vehicle 12. In addition,the remote control 370 can include a display 310 (e.g., a liquid crystaldisplay) and one or more input devices 320, 330 such as buttons and/or atoggle pad. FIGS. 19A-19C show the remote control 370 being used to setup an autonomous vehicle for cleaning. In FIG. 19A, the display 310displays a variety of room types to be cleaned by the autonomousvehicle. In the illustrated embodiment, the user can locate himself andthe remote control 370 in a work area to be cleaned and select from anumber of room type choices, such as bedroom, office, kitchen, utilityroom, living room, dining room, bathroom, and hallway. The system canidentify this room via an encoded and/or modulated emitted signal from anearby transmitter. The user selects one of the room types by pressingan adjacent button 320. Thereafter, the display 310 can acknowledge theuser's selection and automatically connect to a controller (see FIG.19B), such as a personal computer, to allow the user to provide aspecific name for the room. In other embodiments, the remote control cancorrelate the coded emitted signal with the chosen/assigned name andallow a user to choose whether to engage in specific room naming (e.g.,via input 320) or just assign a predetermined name to the room such asbedroom 1, office 1, kitchen 1, etc. Once a room has been assigned anappropriate name, the remote control can allow the user to enteradditional names or continue other aspects of setup. In FIG. 19C, theremote control 370 displays the rooms that have been registered andallows the user to select which rooms are to be cleaned. In theillustrated exemplary embodiment, the user can select one or more of theregistered rooms by pressing an adjacent button 320. The system can thendetermine the order of the rooms to be cleaned and the start time (e.g.,immediately), or can allow the user to determine the order of the roomsto be cleaned end or the start time. In certain embodiments, the systemcan allow the user to select a start time for each selected room.

Another input device 330, shown in the illustrated embodiment as atoggle pad or toggle button, can allow the user to direct the autonomousvehicle to perform a number of functions. For example, the user canpress a center “CLEAN” portion of the toggle button to direct theautonomous vehicle to begin cleaning immediately, or can select theright “DOCK NOW” button to direct the autonomous vehicle to begin ahorning behavior and dock. A top “SCHEDULE” button can be pressed toallow the user to select a schedule of rooms and/or times for cleaning,an exemplary process for which is illustrated in FIGS. 20A-20C. The usercan also select the left “MODES” button to select among a variety ofavailable cleaning modes such as spot clean, deep clean, area rug, drivenow, etc. as illustrated in FIG. 21A. The modes displayed in FIG. 21Acan be selected by pressing a button 320 adjacent a desired mode. Incertain embodiments, after a mode has been selected, the remote control370 can provide further instructions to the user. For example, if an“area rug” mode has been selected, the remote control 370 can displayinstructions confirming that the autonomous vehicle is in “area rug”node and instructing the user to place the autonomous vehicle on thearea rug and then press the central “CLEAN” button. In the illustratedembodiment of FIG. 21B the remote control 370 confirms that the “ROBOTWILL CLEAN THE RUG ONLY.” In another example, if a “DRIVE NOW” mode isselected, the remote control 370 can allow the user to drive thevehicle. In accordance with FIG. 21C, the remote control 370 can informthe user that the autonomous vehicle is in a “DRIVE NOW MODE” andinstruct the user to press certain buttons to drive the robot. Forexample, the top “SCHEDULE” button can be pressed to turn the autonomousvehicle forward, the left “MODES” button can be used to turn the vehicleto the left, the right “DOCK NOW” button can be used to move the vehicleto the right, and the bottom “SETUP” button can be used to move thevehicle backward. One skilled in the art will appreciate that otherbuttons can be used to drive the vehicle, such as, a dedicated drivetoggle or input buttons 320. In certain embodiments, the remote control370 can also inform the user how to exit the “DRIVE NOW” mode, such asby pressing a portion of the toggle button 330.

FIGS. 20A-20C illustrate an exemplary embodiment of cleaning scheduledisplays that can be utilized when the user has pressed the top“SCHEDULE” portion of toggle button 330. In the illustrated exemplaryembodiment, cleaning frequency choices are first displayed for userselection. For example, twice daily, daily, three times per week,weekly, bi-weekly, or monthly can be selected. In certain embodiments, a“CUSTOM” selection can also be made. Users select a frequency bypressing a button adjacent their preferred frequency. In accordance withcertain embodiments, once a frequency has been selected or, if “CUSTOM”is selected, the remote control can display the days of the week forcleaning (see FIG. 20B). The user can select an appropriate number ofdesired days by pressing the button 320 adjacent those days. Inaddition, in accordance with certain embodiments, the user can select atime for cleaning for all selected days or a time for cleaning for eachselected day. Thereafter, as illustrated in FIG. 20C, the user can beprompted by the display 310 to select one or more rooms for cleaning atthe desired date and time. In accordance with various embodiments of thepresent teachings, a user could select “CUSTOM” and set a date and timefor each room registered in accordance with FIGS. 19A-19C, or couldselect a predefined schedule as illustrated in FIG. 20A and personalizethat selection by choosing days and times if desired.

In accordance with certain embodiments of the present teachings, theremote control 370, can also display a status screen such as thatillustrated in FIG. 22. The status screen can have a variety of formatsfor informing the user how much of a scheduled cleaning has beencompleted. The status screen can be accessed in a variety of ways viamanipulation of the remote control 370, or may appear in the manner of ascreen saver when the emote control 370 is not being used forcontrolling an autonomous vehicle or inputting data. One skilled in theart will understand that the selections facilitated by the remotecontrol 370 in FIGS. 19A-22 can also be accomplished via other devices,such as a handheld PDA, a cellular phone, or a laptop or other similarcomputing devices.

Other embodiments of the present teachings will be apparent to thoseskilled in the art from consideration of the specification and practiceof the teachings disclosed herein. It is intended that the specificationand examples be considered as exemplary only, with a true scope andspirit of the present teachings being indicated by the following claims.

1-20. (canceled)
 21. An autonomous robotic cleaning device comprising: arobot body; a drive supporting the robot body above a floor surface of ahome and configured to maneuver the robot body across the floor surface;a cleaning apparatus to clean the floor surface; a processor configuredto wirelessly receive data indicative of a user selection of one or morerooms in the home and a user selection of a schedule to clean the floorsurface in the one or more rooms, and initiate, in accordance to theschedule, one or more cleaning operations, wherein during each of theone or more cleaning operations, the drive maneuvers the autonomousrobotic cleaning device about the floor surface in accordance to theuser selection of the one or more rooms while the cleaning apparatuscleans the floor surface.
 22. The autonomous robotic cleaning device ofclaim 21, wherein the user selection of the one or more rooms in thehome includes a user selection of an order in which to the clean the oneor more rooms in the home, and the processor is configured to, duringthe cleaning operation, navigate the autonomous robotic cleaning deviceabout the one or more rooms in accordance to the user selection of theorder.
 23. The autonomous robotic cleaning device of claim 21, wherein:the user selection of the schedule includes a user-selected frequency inwhich to clean the floor surface, and the processor is configured toinitiate multiple cleaning operations from the one or more cleaningoperations in accordance with the user-selected frequency.
 24. Theautonomous robotic cleaning device of claim 21, wherein the processor isconfigured to assign a unique name to each of the one or more rooms inthe home, wirelessly receive data indicative of a user selection of oneof a plurality of unique names, and control the autonomous roboticcleaning device to clean a room associated with the one of the pluralityof unique names.
 25. The autonomous robotic cleaning device of claim 21,wherein: the user selection of the schedule includes one or moreuser-selected start times at which to initiate the one or more cleaningoperations, and the processor is configured to initiate the one orcleaning operations in accordance to the one or more user-selected starttimes.
 26. The autonomous robotic cleaning device of claim 21, wherein:the user selection of the schedule includes a plurality of start timeseach associated with a corresponding room of the home, and the processoris configured to initiate a plurality of cleaning operations inaccordance to the plurality of start times.
 27. The autonomous roboticcleaning device of claim 21, further comprising a wireless antenna tocommunicate with a remote device, wherein the processor initiatesoperations for the wireless antenna to receive the data from the remotedevice.
 28. The autonomous robotic cleaning device of claim 27, whereinthe remote device includes a cellular phone.
 29. The autonomous roboticcleaning device of claim 21, further comprising a signal receiverconfigured to receive signals emitted through the home, wherein theprocessor is configured to determine in which of the one or more roomsof the home the autonomous robotic cleaning device is located.
 30. Theautonomous robotic cleaning device of claim 21, further comprising anupward-angled camera directed at least partially away from a ceiling ofthe home to capture visible points on wall surfaces within the home, andthe processor is configured to navigate the autonomous robotic cleaningdevice about the home based on a location of the autonomous roboticcleaning device relative to the points.
 31. The autonomous roboticcleaning device of claim 21, wherein the processor is configured toreceive data indicative of a user selection of a docking operation, andinitiate the docking operation in which the drive maneuvers theautonomous robotic cleaning device toward a charging station.
 32. Theautonomous robotic cleaning device of claim 21, wherein the processor isconfigured to receive data indicative of a user-selected movementcommand selected from a forward movement command, a leftward movementcommand, a rightward movement command, and a backward movement command,and initiate drive operations to move the autonomous robotic cleaningdevice in accordance to the user-selected movement command.
 33. Theautonomous robotic cleaning device of claim 21, wherein the processor isconfigured to, responsive to receiving data indicative of auser-selected command to initiate an area rug cleaning operation,initiate the area rug cleaning operation.
 34. The autonomous roboticcleaning device of claim 21, wherein the processor is configured tocreate a map of the home while navigating the autonomous roboticcleaning device about the home to perform the cleaning operation. 35.The autonomous robotic cleaning device of claim 34, further comprising asensor to detect obstacles within one of the one or more rooms, whereinthe processor is configured to: indicate, on the map, an entrapment areabased on an output from the sensors while navigating the autonomousrobotic cleaning device during a first cleaning run, and thencontrolling the autonomous robotic cleaning device using the map toavoid the entrapment area during a subsequent cleaning run.
 36. Theautonomous robotic cleaning device of claim 34, further comprising adirt sensor to detect dirt on the floor surface, wherein the processoris configured to indicate, on the map, readings from the dirt sensor.37. The autonomous robotic cleaning device of claim 21, wherein theprocessor is configured to adjust a cleaning behavior of the autonomousrobotic cleaning device during the one or more cleaning operations inresponse to a signal indicative of a floor type of the floor surface.38. The autonomous robotic cleaning device of claim 21, wherein theprocessor is configured to transmit data indicating how much of the oneor more cleaning operations has been completed, the data comprising datato cause a remote control device to display a floor plan of the roomindicating portions of the floor surface that the autonomous roboticcleaning device has traversed and portions of the floor surface that theautonomous robotic cleaning device has not traversed.
 39. The autonomousrobotic cleaning device of claim 21, wherein the processor is configuredto adjust a cleaning behavior of the autonomous robotic cleaning devicein response to a signal indicative of a floor type of the floor surface.